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Title: 'Cyborg' Tissue Created Using 'Nano-Wires'
Category: Health News
Created: 8/28/2012 6:05:00 PM
Last Editorial Review: 8/29/2012 12:00:00 AM

Title: New Defibrillator Works Without Wires Touching Heart
Category: Health News
Created: 8/26/2013 4:36:00 PM
Last Editorial Review: 8/27/2013 12:00:00 AM

Title: Humans Hardwired to Feel Others' Pain, Study Finds
Category: Health News
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Cyborg: A documentary tells the intriguing story of Neil Harbisson, who wears an antenna to “hear” colour, but it is lacking in depth and should have probed its subject more, says Simon Ings

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Like many innovators, Hagit Messer-Yaron had a life-changing idea while doing something mundane: Talking with a colleague over a cup of coffee. The IEEE Life Fellow, who in 2006 was head of Tel Aviv University’s Porter School of Environmental Studies, was at the school’s cafeteria with a meteorological researcher. He shared his struggles with finding high-resolution weather data for his climate models, which are used to forecast and track flash floods.

Predicting floods is crucial for quickly evacuating residents in affected areas and protecting homes and businesses against damage.

Hagit Messer-Yaron

Employer Tel Aviv University

Title Professor emerita

Member grade Life Fellow

Her colleague “said researchers in the field had limited measurements because the equipment meteorologists used to collect weather data—including radar satellites—is expensive to purchase and maintain, especially in developing countries,” Messer-Yaron says.

Because of that, she says, high-resolution data about temperature, air quality, wind speed, and precipitation levels is often inconsistent—which is a problem when trying to produce accurate models and predictions.

An expert in signal processing and cellular communication, Messer-Yaron came up with the idea of using existing wireless communication signals to collect weather data, as communication networks are spread across the globe.

In 2006 she and her research team developed algorithms that process and analyze data collected by communication networks to monitor rainfall. They measure the difference in amplitude of the signals transmitted and received by the systems to extract data needed to predict flash floods.

The method was first demonstrated in Israel. Messer-Yaron is working to integrate it into communication networks worldwide.

For her work, she received this year’s IEEE Medal for Environmental and Safety Technologies for “contributions to sensing of the environment using wireless communication networks.” The award is sponsored by Toyota.

“Receiving an IEEE medal, which is the highest-level award you can get within the organization, was really a surprise, and I was extremely happy to [receive] it,” she says. “I was proud that IEEE was able to evaluate and see the potential in our technology for public good and to reward it.”

A passion for teaching

Growing up in Israel, Messer-Yaron was interested in art, literature, and science. When it came time to choose a career, she found it difficult to decide, she says. Ultimately, she chose electrical engineering, figuring it would be easier to enjoy art and literature as hobbies.

After completing her mandatory service in the Israel Defense Forces in 1973, she began her undergraduate studies at Tel Aviv University, where she found her passion: Signal processing.

“Electrical engineering is a very broad topic,” she says. “As an undergrad, you learn all the parts that make up electrical engineering, including applied physics and applied mathematics. I really enjoyed applied mathematics and soon discovered signal processing. I found it quite amazing how, by using algorithms, you can direct signals to extract information.”

She graduated with a bachelor’s degree in EE in 1977 and continued her education there, earning master’s and doctoral degrees in 1979 and 1984. She moved to the United States for a postdoctoral position at Yale. There she worked with IEEE Life Fellow Peter Schultheiss, who was known for his research in using sensor array systems in underwater acoustics.

Inspired by Schultheiss’s passion for teaching, Messer-Yaron decided to pursue a career in academia. She was hired by Tel Aviv University as an electrical engineering professor in 1986. She was the first woman in Israel to become a full professor in the subject.

“Being a faculty member at a public university is the best job you can do. I didn’t make a lot of money, but at the end of each day, I looked back at what I did [with pride].”

For the next 14 years, she conducted research in statistical signal processing, time-delay estimation, and sensor array processing.

Her passion for teaching took her around the world as a visiting professor at Yale, the New Jersey Institute of Technology, the Institut Polytechnique de Paris, and other schools. She collaborated with colleagues from the universities on research projects.

In 1999 she was promoted to director of Tel Aviv University’s undergraduate electrical engineering program.

A year later, she was offered an opportunity she couldn’t refuse: Serving as chief scientist for the Israeli Ministry of Science, Culture, and Sports. She took a sabbatical from teaching and for the next three years oversaw the country’s science policy.

“I believe [working in the public sector] is part of our duty as faculty members, especially in public universities, because that makes you a public intellectual,” she says. “Working for the government gave me a broad view of many things that you don’t see as a professor, even in a large university.”

When she returned to the university in 2004, Messer-Yaron was appointed as the director of the new school of environmental studies. She oversaw the allocation of research funding and spoke with researchers individually to better understand their needs. After having coffee with one researcher, she realized there was a need to develop better weather-monitoring technology.

Hagit Messer-Yaron proudly displays her IEEE Medal for Environmental and Safety Technologies at this year’s IEEE Honors Ceremony. She is accompanied by IEEE President-Elect Kathleen Kramer and IEEE President Tom Couglin.Robb Cohen

Using signal processing to monitor weather

Because the planet is warming, the risk of flash floods is steadily increasing. Warmer air holds more water—which leads to heavier-than-usual rainfall and results in more flooding, according to the U.S. Environmental Protection Agency.

Data about rainfall is typically collected by satellite radar and ground-based rain gauges. However, radar images don’t provide researchers with precise readings of what’s happening on the ground, according to an Ensia article. Rain gauges are accurate but provide data from small areas only.

So Messer-Yaron set her sights on developing technology that connects to cellular networks close to the ground to provide more accurate measurements, she says. Using existing infrastructure eliminates the need to build new weather radars and weather stations.

Communication systems automatically record the transmitted signal level and the received signal level, but rain can alter otherwise smooth wave patterns. By measuring the difference in the amplitude, meteorologists could extract the data necessary to track rainfall using the signal processing algorithms.

In 2005 Messer-Yaron and her group successfully tested the technology. The following year, their “Environmental Monitoring by Wireless Communication Networks” paper was published in Science.

The algorithm is being used in Israel in partnership with all three of the country’s major cellular service providers. Messer-Yaron acknowledges, however, that negotiating deals with cellular service companies in other countries has been difficult.

To expand the technology’s use worldwide, Messer-Yaron launched a research network through the European Cooperation in Science and Technology (COST), called an opportunistic precipitation sensing network known as OPENSENSE. The group connects researchers, meteorologists, and other experts around the world to collaborate on integrating the technology in members’ communities.

Monitoring the effects of climate change

Since developing the technology, Messer-Yaron has held a number of jobs including president of the Open University of Israel and vice chair of the country’s Council for Higher Education, which accredits academic institutions.

She is maintaining her link with Tel Aviv University today as a professor emerita.

“Being a faculty member at a public university is the best job you can do,” she says. “I didn’t make a lot of money, but at the end of each day, I looked back at what I did [with pride]. Because of the academic freedom and the autonomy I had, I was able to do many things in addition to teaching, including research.”

To continue her work in developing technology to monitor weather events, in 2016, she helped found ClimaCell, now Tomorrow.io, based in Boston. The startup aims to use wireless communication infrastructure and IoT devices to collect real-time weather data. Messer-Yaron served as its chief scientist until 2017.

She continues to update the original algorithms with her students, most recently with machine learning capabilities to extract data from physical measurements of the signal level in communication networks.

A global engineering community

When Messer-Yaron was an undergraduate student, she joined IEEE at the suggestion of one of her professors.

“I didn’t think much about the benefits of being a member until I became a graduate student,” she says. “I started attending conferences and publishing papers in IEEE journals, and the organization became my professional community.”

She is an active volunteer and a member of the IEEE Signal Processing Society. From 1994 to 2010 she served on the society’s Signal Processing Theory and Methods technical committee. She was associate editor of IEEE Signal Processing Letters and IEEE Transactions on Signal Processing. She is a member of the editorial boards of the IEEE Journal of Selected Topics in Signal Processing and IEEE Transactions on Signal Processing.

In the past 10 years, she’s been involved with other IEEE committees including the conduct review, ethics and member conduct, and global public policy bodies.

“I don’t see my career or my professional life without the IEEE,” she says

Rode has announced the Wireless Micro, a two-mic kit with a smartphone receiver and charging case that costs just $149. The idea is to help TikTok and other creators capture much better-quality audio than their smartphone's microphone can offer. 

The receiver unit connects to the bottom of your smartphone via a USB-C or lightning port. Meanwhile, the microphones (aka transmitters) attach to the subject via integrated clips or magnetic attachments, then capture what Rode calls "pristine" quality sound. Specifically, they offer a 20-20 kHz frequency range and 73 dB signal-to-noise ratio, with a transmission range around 330 feet.

To use it, simply connect the receiver to your iOS or Android device and it will take over as the system microphone. From there, everything is automatic, as the transmitter mics are automatically paired to the receiver and sound will be captured to your camera app of choice. Levels are automatically controlled with the company's GainAssist technology. 

The omnidirectional transmitters weigh just 12 grams (0.42 ounces) and are tiny enough to be discreet when clipped onto your subject. The built-in microphones use what Rode calls "acoustic chambers" with a patent-pending design. That supposedly lets you capture clear and intelligible audio while reducing wind noise, though a pair of windmuffs is also included in the kit. 

The Wireless Micro also includes a charging case that delivers two full recharges for up to 18 hours of battery life, while giving you a secure place to store everything. 

There are a few things missing, though. You can't connect an external mic to the transmitters, unlike with other Rode wireless mics or the DJI Mic 2. There's no smartphone Bluetooth capability, and it doesn't offer a 3.5mm connection for cameras — a feature that will supposedly exist on the rumored DJI Mic Mini. Still, this looks like a great option for creators who primarily use smartphones. It's now available in a two mic kit with a receiver and charging case for $150. 

UPDATE 31 OCTOBER 2024: No. 1 no longer. The would-have-been groundbreaking study published in Nature Communications by Amit Goyal et al. claiming the world’s highest-performing high-temperature superconducting wires yet has been retracted by the authors.

The journal’s editorial statement that now accompanies the paper says that after publication, an error in the calculation of the reported performance was identified. All of the study’s authors agreed with the retraction.

The researchers were first alerted to the issue by Evgeny Talantsev at the Mikheev Institute of Metal Physics in Ekaterinburg, Russia, and Jeffery Tallon at the Victoria University of Wellington in New Zealand. In a 2015 study, the two researchers had suggested upper limits for thin-film superconductors, and Tallon notes follow-up papers showed these limits held for more than 100 known superconductors. “The Goyal paper claimed current densities 2.5 times higher, so it was immediately obvious to us that there was a problem here,” he says.

Upon request, Goyal and his colleagues “very kindly agreed to release their raw data and did so quickly,” Tallon says. He and Talantsev discovered a mistake in the conversion of magnetization units.

“Most people who had been in the game for a long time would be fully conversant with the units conversion because the instruments all deliver magnetic data in [centimeter-gram-second] gaussian units, so they always have to be converted to [the International System of Units],” Tallon says. “It has always been a little tricky, but students are asked to take great care and check their numbers against other reports to see if they agree.”

In a statement, Goyal notes he and his colleagues “intend to continue to push the field forward” by continuing to explore ways to enhance wire performance using nanostructural modifications. —Charles Q. Choi

Original article from 17 August, 2024 follows:

Superconductors have for decades spurred dreams of extraordinary technological breakthroughs, but many practical applications for them have remained out of reach. Now a new study reveals what may be the world’s highest-performing high-temperature superconducting wires yet, ones that carry 50 percent as much current as the previous record-holder. Scientists add this advance was achieved without increased costs or complexity to how superconducting wires are currently made.

Superconductors conduct electricity with zero resistance. Classic superconductors work only at super-cold temperatures below 30 degrees Kelvin. In contrast, high-temperature superconductors can operate at temperatures above 77 K, which means they can be cooled to superconductivity using comparatively inexpensive and less burdensome cryogenics built around liquid nitrogen coolant.

Regular electrical conductors all resist electron flow to some degree, resulting in wasted energy. The fact that superconductors conduct electricity without dissipating energy has long lead to dreams of significantly more efficient power grids. In addition, the way in which rivers of electric currents course through them means superconductors can serve as powerful electromagnets, for applications such as maglev trains, better MRI scanners for medicine, doubling the amount of power generated from wind turbines, and nuclear fusion power plants.

“Today, companies around the world are fabricating kilometer-long, high-temperature superconductor wires,” says Amit Goyal, SUNY Distinguished Professor and SUNY Empire Innovation Professor at the University of Buffalo in New York.

However, many large-scale applications for superconductors may stay fantasies until researchers can find a way to fabricate high-temperature superconducting wires in a more cost-effective manner.

In the new research, scientists have created wires that have set new records for the amount of current they can carry at temperatures ranging from 5 K to 77 K. Moreover, fabrication of the new wires requires processes no more complex or costly than those currently used to make high-temperature superconducting wires.

“The performance we have reported in 0.2-micron-thick wires is similar to wires almost 10 times thicker,” Goyal says.

At 4.2 K, the new wires carried 190 million amps per square centimeter without any externally applied magnetic field. This is some 50 percent better than results reported in 2022 and a full 100 percent better than ones detailed in 2021, Goyal and his colleagues note. At 20 K and under an externally applied magnetic field of 20 tesla—the kind of conditions envisioned for fusion applications—the new wires may carry about 9.3 million amps per square centimeter, roughly 5 times greater than present-day commercial high-temperature superconductor wires, they add.

Another factor key to the success of commercial high-temperature superconductor wires is pinning force—the ability to keep magnetic vortices pinned in place within the superconductors that could otherwise interfere with electron flow. (So in that sense higher pinning force values are better here—more conducive to the range of applications expected for such high-capacity, high-temperature superconductors.) The new wires showed record-setting pinning forces of more than 6.4 trillion newtons at 4.3 K under a 7 tesla magnetic field. This is more than twice as much as results previously reported in 2022.

The new wires are based on rare-earth barium copper oxide (REBCO). The wires use nanometer-sized columns of insulating, non-superconducting barium zirconate at nanometer-scale spacings within the superconductor that can help pin down magnetic vortices, allowing for higher supercurrents.

The researchers made these gains after a few years spent optimizing deposition processes, Goyal says. “We feel that high-temperature superconductor wire performance can still be significantly improved,” he adds. “We have several paths to get to better performance and will continue to explore these routes.”

Based on these results, high-temperature superconductor wire manufacturers “will hopefully further optimize their deposition conditions to improve the performance of their wires,” Goyal says. “Some companies may be able to do this in a short time.”

The hope is that superconductor companies will be able to significantly improve performance without too many changes to present-day manufacturing processes. “If high-temperature superconductor wire manufacturers can even just double the performance of commercial high-temperature superconductor wires while keeping capital equipment costs the same, it could make a transformative impact to the large-scale applications of superconductors,” Goyal says.

The scientists detailed their findings on 7 August in the journal Nature Communications.

This story was updated on 19 August 2024 to correct Amit Goyal’s title and affiliation.

No Blank Screens, London

In the rapidly advancing landscape of AI technology and innovation, LimeWire emerges as a unique platform in the realm of generative AI tools. This platform not only stands out from the multitude of existing AI tools but also brings a fresh approach to content generation. LimeWire not only empowers users to create AI content but also provides creators with creative ways to share and monetize their creations.

As we explore LimeWire, our aim is to uncover its features, benefits for creators, and the exciting possibilities it offers for AI content generation. This platform presents an opportunity for users to harness the power of AI in image creation, all while enjoying the advantages of a free and accessible service.

Let's unravel the distinctive features that set LimeWire apart in the dynamic landscape of AI-powered tools, understanding how creators can leverage its capabilities to craft unique and engaging AI-generated images.

Introduction

This revamped LimeWire invites users to register and unleash their creativity by crafting original AI content, which can then be shared and showcased on the LimeWire Studio. Notably, even acclaimed artists and musicians, such as Deadmau5, Soulja Boy, and Sean Kingston, have embraced this platform to publish their content in the form of NFT music, videos, and images.

Beyond providing a space for content creation and sharing, LimeWire introduces monetization models to empower users to earn revenue from their creations. This includes avenues such as earning ad revenue and participating in the burgeoning market of Non-Fungible Tokens (NFTs). As we delve further, we'll explore these monetization strategies in more detail to provide a comprehensive understanding of LimeWire's innovative approach to content creation and distribution.

LimeWire Studio welcomes content creators into its fold, providing a space to craft personalized AI-focused content for sharing with fans and followers. Within this creative hub, every piece of content generated becomes not just a creation but a unique asset—ownable and tradable. Fans have the opportunity to subscribe to creators' pages, immersing themselves in the creative journey and gaining ownership of digital collectibles that hold tradeable value within the LimeWire community. Notably, creators earn a 2.5% royalty each time their content is traded, adding a rewarding element to the creative process.

The platform's flexibility is evident in its content publication options. Creators can choose to share their work freely with the public or opt for a premium subscription model, granting exclusive access to specialized content for subscribers.

LimeWire AI Studio

As of the present moment, LimeWire focuses on AI Image Generation, offering a spectrum of creative possibilities to its user base. The platform, however, has ambitious plans on the horizon, aiming to broaden its offerings by introducing AI music and video generation tools in the near future. This strategic expansion promises creators even more avenues for expression and engagement with their audience, positioning LimeWire Studio as a dynamic and evolving platform within the realm of AI-powered content creation.

AI Image Generation Tools

The LimeWire AI image generation tool presents a versatile platform for both the creation and editing of images. Supporting advanced models such as Stable Diffusion 2.1, Stable Diffusion XL, and DALL-E 2, LimeWire offers a sophisticated toolkit for users to delve into the realm of generative AI art.

Much like other tools in the generative AI landscape, LimeWire provides a range of options catering to various levels of complexity in image creation. Users can initiate the creative process with prompts as simple as a few words or opt for more intricate instructions, tailoring the output to their artistic vision.

What sets LimeWire apart is its seamless integration of different AI models and design styles. Users have the flexibility to effortlessly switch between various AI models, exploring diverse design styles such as cinematic, digital art, pixel art, anime, analog film, and more. Each style imparts a distinctive visual identity to the generated AI art, enabling users to explore a broad spectrum of creative possibilities.

The platform also offers additional features, including samplers, allowing users to fine-tune the quality and detail levels of their creations. Customization options and prompt guidance further enhance the user experience, providing a user-friendly interface for both novice and experienced creators.

Excitingly, LimeWire is actively developing its proprietary AI model, signaling ongoing innovation and enhancements to its image generation capabilities. This upcoming addition holds the promise of further expanding the creative horizons for LimeWire users, making it an evolving and dynamic platform within the landscape of AI-driven art and image creation.

Sign Up Now To Get Free Credits

Automatically Mint Your Content As NFTs

Upon completing your creative endeavor on LimeWire, the platform allows you the option to publish your content. An intriguing feature follows this step: LimeWire automates the process of minting your creation as a Non-Fungible Token (NFT), utilizing either the Polygon or Algorand blockchain. This transformative step imbues your artwork with a unique digital signature, securing its authenticity and ownership in the decentralized realm.

Creators on LimeWire hold the power to decide the accessibility of their NFT creations. By opting for a public release, the content becomes discoverable by anyone, fostering a space for engagement and interaction. Furthermore, this choice opens the avenue for enthusiasts to trade the NFTs, adding a layer of community involvement to the artistic journey.

Alternatively, LimeWire acknowledges the importance of exclusivity. Creators can choose to share their posts exclusively with their premium subscribers. In doing so, the content remains a special offering solely for dedicated fans, creating an intimate and personalized experience within the LimeWire community. This flexibility in sharing options emphasizes LimeWire's commitment to empowering creators with choices in how they connect with their audience and distribute their digital creations.

After creating your content, you can choose to publish the content. It will automatically mint your creation as an NFT on the Polygon or Algorand blockchain. You can also choose whether to make it public or subscriber-only.

If you make it public, anyone can discover your content and even trade the NFTs. If you choose to share the post only with your premium subscribers, it will be exclusive only to your fans.

Earn Revenue From Your Content

Additionally, you can earn ad revenue from your content creations as well.

When you publish content on LimeWire, you will receive 70% of all ad revenue from other users who view your images, music, and videos on the platform.

This revenue model will be much more beneficial to designers. You can experiment with the AI image and content generation tools and share your creations while earning a small income on the side.

LMWR Tokens

The revenue you earn from your creations will come in the form of LMWR tokens, LimeWire’s own cryptocurrency.

Your earnings will be paid every month in LMWR, which you can then trade on many popular crypto exchange platforms like Kraken, ByBit, and UniSwap.

You can also use your LMWR tokens to pay for prompts when using LimeWire generative AI tools.

Pricing Plans

You can sign up to LimeWire to use its AI tools for free. You will receive 10 credits to use and generate up to 20 AI images per day. You will also receive 50% of the ad revenue share. However, you will get more benefits with premium plans.

• Basic plan: 

For $9.99 per month, you will get 1,000 credits per month, up to 2 ,000 image generations, early access to new AI models, and 50% ad revenue share

• Advanced plan: 

For $29 per month, you will get 3750 credits per month, up to 7500 image generations, early access to new AI models, and 60% ad revenue share

• Pro plan: 

For $49 per month, you will get 5,000 credits per month, up to 10,000 image generations, early access to new AI models, and 70% ad revenue share

• Pro Plus plan: 

For $99 per month, you will get 11,250 credits per month, up to 2 2,500 image generations, early access to new AI models, and 70% ad revenue share

With all premium plans, you will receive a Pro profile badge, full creation history, faster image generation, and no ads.

Sign Up Now To Get Free Credits

Conclusion

In conclusion, LimeWire emerges as a democratizing force in the creative landscape, providing an inclusive platform where anyone can unleash their artistic potential and effortlessly share their work. With the integration of AI, LimeWire eliminates traditional barriers, empowering designers, musicians, and artists to publish their creations and earn revenue with just a few clicks.

The ongoing commitment of LimeWire to innovation is evident in its plans to enhance generative AI tools with new features and models. The upcoming expansion to include music and video generation tools holds the promise of unlocking even more possibilities for creators. It sparks anticipation about the diverse and innovative ways in which artists will leverage these tools to produce and publish their own unique creations.

For those eager to explore, LimeWire's AI tools are readily accessible for free, providing an opportunity to experiment and delve into the world of generative art. As LimeWire continues to evolve, creators are encouraged to stay tuned for the launch of its forthcoming AI music and video generation tools, promising a future brimming with creative potential and endless artistic exploration

PlayStation fans can look forward to a diverse lineup of games this November, as Sony has announced three new titles for its PlayStation Plus subscribers: the eerie action-adventure Ghostwire: Tokyo, the social deduction game Death Note: Killer Within, and the high-speed

ASUS has introduced the Wireless Mouse MD102 in India, offering a blend of durability and wireless dependability in an ergonomic design. Available in Dark Grey and White, this stylish mouse is priced at Rs 1799 and will be available from September

The new Netflix anthology, based on the works of Satyajit Ray, is an exploration of minds in the throes of existential crises